Investigation of Cold Pressure Welding: Cohesion Coefficient of Copper-Reference-Cited by-同舟云学术

Investigation of Cold Pressure Welding: Cohesion Coefficient of Copper

Published:2015-07 Issue: Volume:651-653 Page:1421-1426
ISSN:1662-9795
Container-title:Key Engineering Materials
language:
Short-container-title:KEM

Author:

Schmidt Hans Christian¹,Ebbert Christoph²,Rodman Dmytro³,Homberg Werner¹,Grundmeier Guido¹,Maier Hans Jurgen³

Affiliation:

1. University of Paderborn

2. Universität Paderborn

3. Leibniz Universität Hannover

Abstract

Joining materials by forming is an interesting approach to the manufacture of hybrid (multi material) parts. By establishing a cold pressure weld between metallic surfaces, high quality joints with superior properties can be achieved. Reliable cold welding conditions are difficult to set up, however, since the weld initiation requires extraordinary clean, virtually sheer surfaces. Until today such conditions could only be achieved under a high vacuum conditions. Various studies on cold pressure welding reported that under vacuum welds can be established at significantly lower deformation than in a normal atmosphere. Since adverse deformation is currently needed in industrial cold pressure welding processes like the cold roll cladding of metal bands, a new process with in-line electrochemical surface treatment, is investigated. The ECUF process is intended to supply clean and thereby highly activated surfaces to the cold pressure welding process.This paper presents first results on the weld-ability of copper specimens with regard to the influence of the welding environment: air, argon and KCl solution. Butt welds were made by pressure welding of previously fractured specimens.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,General Materials Science

Link

https://www.scientific.net/KEM.651-653.1421.pdf

Reference9 articles.

1. L. Li, K. Nagai, and F. Yin. Progress in cold roll bonding of metals. Science and Technology of Advanced Materials, 9(2): 023001, (2008).

2. N. Bay. Mechanism producing metallic bonds in cold welding. Welding Research Supplement, 62(5): 137-s-142s, (1983).

3. M. K¨ohler. Plattiertes Stahlblech. Merkblatt 383, Stahl-Informations-Zentrum, D¨usseldorf, (2006).

4. C. Ebbert, H. C. Schmidt, D. Rodman, F. N¨urnberger, W. Homberg, H. J. Maier, and G. Grundmeier. Joining with electrochemical support (ECUF): Cold pressure welding of copper. Journal of Materials Processing Technology, 214(10): 2179-2187, (2014).

5. W. P Gilbreath and H. T. Sumsion. Solid-phase welding of metals under high vacuum. Journal of Spacecraft and Rockets, 3(5): 674-679, (1966).

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